Actuating Element for a Telescopic Sight

ABSTRACT

The invention relates to an actuating element for setting the aim mark of a telescopic sight. According to the invention, the actuating element is rotatbly located on the telescopic sight in the form of a rotary knob and the aim mark is displaced in a vertical and/or horizontal direction by means of a mechanical actuator, when the rotary knob is turned. In addition, the rotational area of the rotary knob is restricted in both rotational directions by at least one working region stop. The rotary knob is detachably coupled to the mechanical actuator. The working region stop(s) can be deactivated, allowing the rotary knob to be turned beyond the working region stop in both directions. The actuating element can be switched between at least three different modes. In mode A, the rotary knob is coupled to the mechanical actuator and the working region stop is inactive. In mode B, the rotary knob is decoupled from the mechanical actuator when the working region stop is active and in mode C, the rotary knob is coupled to the mechanical actuator and the working region stop is active.

The invention relates to an actuator for adjusting the position of the lead mark of a telescopic sight, the actuator being in the form of a rotary knob mounted for rotation on the telescopic sight, rotation of said knob causing the lead mark to be adjusted by means of an adjusting mechanism in a vertical and/or horizontal direction while the turning range of the rotary knob is restricted by at least one operating range limit stop in both directions of rotation.

Telescopic sights have a lead mark, for example in the form of a reticle. In order to be able to adjust the lead mark to the actual point of impact for specific ballistics (caliber, projectile mass, type of projectile, charge, etc.) and a specific barrel for a specific zero range, the lead mark is usually adjustable for elevation and deflection in known manner by means of an adjusting mechanism.

In addition, different construction designs have been disclosed that make it possible to index the adjusted position by means of an index mark (zeroing).

With such designs, however, it is usually only possible to index one specific setting, ie only one zero mark, for the point of impact for specific ballistics using a specific barrel for just one shooting range.

An actuator of the type described at the outset for use on a telescopic sight and enabling multiple zeroing, ie zeroing for a number of ranges and/or for different ballistics and/or different gun barrels etc., is disclosed, for example, by Leatherwood (USA) under the name of “Uni-Dial” (see also US 2004/0144013 A1). This actuator exhibits a number of indicator flags that can be rotated in the actuator. The actuator is embodied in the form of a rotary knob that consists of several disk-shaped elements positioned around the axis of rotation of the unit. The flags are disposed on flat disks located between the disk-shaped elements of the rotary knob (turret) (in the disclosed embodiment the disk-shaped elements of the rotary knob are substantially thicker than the disks having the flags) and are displaceable in an adjustment mode of the actuator, ie the disks on which the flags are located can be rotated about the axis of rotation without the lead mark itself being displaced.

In the operating mode, after zeroing for different ranges, barrels, etc., the flags are fixed in their adjusted position by screwing, or otherwise fixing, the rotary knob, that is to say, the plates that form the rotary knob, such that the said plates are pressed tightly against each other so that the flag indicator plates are squeezed between the disks of the rotary knob and are entrained with the knob when the latter is rotated.

Irrespective of whether only “single” indexing or “multiple” indexing is possible when using an actuator of the aforementioned type, an actuator has a given adjustment range for control of the lead mark. This adjustment range is limited by at least one operating range limit stop. Either two separate operating range limit stops are provided that restrict the rotary motion of the rotary knob, or only one operating range limit stop serves as both the upper and lower stop, while, depending on the dimensions of the operating range limit stop device, a turn of almost 360° is possible, typically approx. 330°. The limitation of the overall range of possible adjustment to one adjustment range serves to avoid indexing ambiguities.

Actuators have also been disclosed in which the adjustment range is not restricted by means of operating range limit stops. To enable a user to know at what position the rotary knob is set, ie how many turns the rotary knob has made starting from an initial setting, horizontal bars are provided which are either hidden or made visible as the rotary knob is turned.

Such a system makes an additional adjustment range of the lead mark possible. Such a system is of particular interest to the military. Since in such systems the individual index marks are defined by vertical bars and thus a large number of adjustments is possible, the user of such a rifle needs, for use, lists in which the individual index marks are defined, particularly in connection with the number of full turns of the rotary knob.

Such a high degree of accuracy is not necessary in hunting, and the shooting ranges encountered in hunting are restricted to a significantly narrower range than that required by the military.

On the other hand, in hunting it is necessary that the lead mark of a sight of a rifle can be indexed simply and quickly and without the use of said lists, eg for four different ranges, and that such ranges can be quickly and simply set by the user. For this reason, in hunting, actuators for telescopic sights are mainly used that have an operating range limit stop as is the case on the aforementioned telescopic sight sold by Leatherwood.

With this telescopic sight, the operating range limit stop is defined by a screw that can be loosened. By loosening and turning the screw along the periphery of the actuator, the stopping point and thus the adjustment range of the lead mark can be adjusted in relation to the entire possible adjustment range.

This solution, however, has some drawbacks in practice. The procedure of loosening, turning, and subsequently tightening the screw is relatively complicated. There is a risk of losing the screw. In addition, the system can become contaminated with dirt relatively easily, which might lead to deterioration of the adjustability.

It is an object of the invention to eliminate the aforementioned disadvantages.

According to the invention, this object is achieved on an actuator of the type described at the outset in that

-   -   the rotary knob is releasably attached to the adjusting         mechanism,     -   at least one operating range limit stop is capable of being         deactivated such that the rotary knob can be turned in both         directions beyond the operating range limit stop, and     -   the actuator can be switched between at least three different         modes of operation, viz:     -   a) in mode A the rotary knob is coupled to the adjusting         mechanism and the operating range limit stop is inactive,     -   b) in mode B the rotary knob is decoupled from the adjusting         mechanism and the operating range limit stop is activated, and     -   c) in mode C the rotary knob is coupled to the adjusting         mechanism and the operating range limit stop is activated.

Due to the disconnectable coupling of the turret to the adjusting mechanism, the entire mechanics for activating and deactivating the limit stop can be integrated in the turret while maintaining full adjustability. In this way, contamination is prevented and no components can be lost. Adjustment and operation of the telescopic sight is made substantially easier due to the ability to set the actuator to different modes, with two of these serving to set up the basic settings and the third representing the actual “operating mode” in which the lead mark is brought into a position that corresponds to a particular shooting range by turning the rotary knob.

In a specific, advantageous embodiment, a limit stop element is placed inside the rotary knob, which butts against an operating range limit stop when it is turned in a first, lower position, so that the operating range limit stop is active, and which moves beyond the limit stop element when it is turned in a second, upper position, so that the operating range limit stop is deactivated. Due to the fact that the entire stopping mechanism is inside the rotary knob or actuator, the aforementioned advantages are realized and the disadvantages discussed above are avoided.

The subject matter of the invention can be realized and assembled particularly easily if the stopping element is a pin which can be displaced in a direction parallel to the axis of rotation.

For coupling and decoupling the rotary knob to and from the adjusting mechanism, the rotary knob is connected to a first coupler element that is adapted to engage a second coupler element that is connected to the adjusting mechanism, so that turning the rotary knob entrains the adjusting mechanism, the first and second clutch systems being detachable from each other.

In a specific embodiment, the stopping element and the first coupler element are separate entities, this being the simplest variant from the point of view of manufacturing technology and design engineering.

The limit stop element and the first coupler element could alternatively be designed as a single unit to the effect that, for instance, the limit stop element is mounted for vertical displacement in the first coupler element in the form of a pin. This is an elegant variant which saves space inside the rotary knob, but it is more complicated as regards kinematics and manufacturing.

In principle, however, the limit stop element and the first coupler element could indeed be made as a single unit.

A simple embodiment that makes a reliable and readily deactivated coupler possible and that, in addition, has a multiplicity of possible coupler positions between the rotary knob and the adjusting mechanism, is realized when the second coupler element comprises one or more orifices or projections that is/are positioned at the periphery of the adjusting mechanism and when the first coupler element is a projection or orifice respectively, whilst in the coupled state a projection engages an orifice.

Alternatively, the first and second coupler elements can form a friction clutch, for example in that the first coupler element is a projection with a rubber lug that engages a rubber band disposed around the adjusting mechanism in its peripheral direction.

Simple engagement or disengagement of the clutch can be realized if the first or second coupler element can be displaced in a direction parallel to the axis of rotation for disengagement of the clutch.

For example, the second coupler element could be pushed downwardly against the force of a spring.

A particularly simple, ergonomic, and dirt-insensitive method of adjustment is realized when a control element that can be rotated about the axis of rotation of the rotary knob is disposed inside the rotary knob and at least one operating cam moves round the periphery thereof, which cam cooperates with the limit stop element and the first coupler element, the at least one operating cam exhibiting a continuous path that features a rising or falling course in certain regions of the periphery.

In the case of a limit stop element which is separate from the first coupler element, it is sufficient to have just one operating cam on the control element which, for instance, lifts the first coupler element from the second coupler element when it is turned through its particular path, while the limit stop remains active, etc.

If the two elements can be interleaved, as described above, and thus be disposed one directly above the other, a separate operating cam is necessary for each element (limit stop element and first coupler element).

The control element can be fixed relatively to the rotary knob to prevent the control element from being rotated unintentionally to activate another mode when the rotary knob is turned.

The said effect can be realized in an even simpler manner with the same results, if the control element is coupled to the rotary knob by means of a friction clutch or a power clutch. In the case of a frictional connection between the rotary knob and the control element, rotation of the control element by applying appropriate force thereto while simultaneously gripping the rotary knob is sufficient to activate another mode. If, however, the rotary knob is rotated, the control element is simply entrained by the friction forces between the rotary knob and the control element.

The control element is itself conveniently mounted for rotation in the rotary knob, and the top cover face of the control element is substantially flush with the cover face of the rotary knob.

In order to enable simple rotation of the control element and thus activate the various modes, the control element exhibits one or more orifices on its top surface for the accommodation of a key, and by way of the key the control element can be turned relatively to the rotary knob.

When a friction clutch is disposed between the control element and the rotary knob, this key simply serves to make it easier to turn the control element in the rotary knob but does not have any key “function” in the sense of something being “locked”.

However, any means for fixing the position of the control element relatively to the rotary knob can be disengaged and re-engaged with the key if such mechanical fixating means are provided. In the case of disengaged fixation, the control element can simply be rotated with the key.

In order to indicate the position of the lead mark in relation to the entire range, the adjusting mechanism exhibits a displacement indicator in its upper region which is moved up or down by rotating the adjusting mechanism in a direction parallel to the axis of rotation in an appropriate opening in the control element, which indicator, depending on position, is either flush with, projects above, or is positioned below, the cover surface of the rotary knob and/or the cover surface of the control element.

This displacement indicator can be in the form of an attachment to the adjusting mechanism, for example, or the said indicator and the adjusting mechanism can alternatively be made as a single unit. The displacement indicator is raised or lowered appropriately by means of the up and down movements of the adjusting mechanism, ie the spindle. If the displacement indicator is already very far inside or outside the actuator following assembly and an initial set-up of the telescopic sight, this points to poor assemblage, which can result in the adjustment range no longer being fully exploited.

Using the Leatherwood telescopic sight described above in its operating mode, the flags are fixed in their adjusted positions after zeroing to different shooting ranges, barrels, etc. by screwing or otherwise locking the rotary knob, ie the plates forming the adjustment knob, to each other, the flag indicator plates being squeezed between the plates of the rotary knob and entrained therewith when the rotary knob is turned.

The disadvantage of this system, however, is that in order to adjust the individual flags, the rotary knob must be “loosened”, ie its clamping action must be released such that the turret plates become slightly displaceable along the axis of rotation and the flags, or rather the plates carrying the flags, become rotatable. However, for this purpose, the tower must be slackened in a separate procedure, on the one hand, and, on the other hand, this leads—particularly detrimentally—to all flags becoming loose so that flags that have already been adjusted can be easily accidentally moved from their settings.

In order to improve an actuator of the type mentioned above allowing maximum versatility of indexing, such that

-   -   it is generally easier to use as regards multiple indexing, and     -   it permits stable positioning of the indexing elements already         set, even in the case of uncompleted indexing or renewed         indexing for one or more other indexing elements,         it is further provided that the rotary knob exhibits one or more         recesses in the peripheral direction on its lateral surface, at         least one indexing element being rotatably mounted in at least         one recess, and said one or more indexing elements in their         recesses being coupled in such a manner with the rotary knob         that they are entrained by the knob when the latter is turned.

In an actuator of the invention, the indexing elements can be moved independently of each other, since loosening of the turret is not necessary and the indexing elements are disposed separately from each other in their own recesses. Unintentional displacement of an index mark during the zeroing procedure can therefore be easily prevented.

With the invention, a so-called “indexing mode”, in which the index marks are displaceable as in the aforementioned prior art, no longer exists, but rather the indexing elements are, in principle, adjustable at any time by means of the special embodiment of the invention. Any unintentional simultaneous displacement of the indexing elements is not, or only hardly, possible.

In principle, the invention is also realizable and meaningful with only one indexing element. The use of a number of indexing elements does, however, have a special advantage, since this makes it possible for the user to index different shooting ranges and/or different ballistic situations and/or different barrels or exchangeable barrels using the same telescopic sight, as required.

Neither is it necessary, in principle, to have at least one indexing element in each recess. However, it is a sensible and convenient arrangement to have at least one indexing element in each recess, since this provides a large number of adjustment possibilities, depending on the number of recesses.

If the indexing elements are coupled to the rotary element in the recesses by means of friction-type clutches, the indexing elements can be adjusted easily and with minimum effort. In a specific embodiment, coupling is effected by means of a friction connection, in which case the indexing elements can be easily rotated by exerting force on the adjustment knob (while the rotary knob is held firmly by the user). When the rotary knob is itself turned, however, there occurs no adjustment of the indexing elements. No additional mechanical elements, such as screws etc., are necessary for fixing the indexing elements when coupling is effected via friction means, which means that adjustments are easier to carry out and the actuator is simpler and more economical to manufacture.

Unwanted adjustment of the position of an indexing element when adjusting another indexing element is then optimally prevented when just one indexing element is present in each recess.

If the one or more recesses each form a closed ring on the lateral surface, a particularly large adjustment range for the individual indexing element is created.

An optimal fit and hold as well as an easy, unhindered adjustment of the indexing elements are possible if an indexing element is formed in the form of a ring section or a closed ring.

In particular, if an indexing element is designed in the form of a closed ring, it is necessary that it exhibits a mark, which is brought into register with a fixed “zero mark”, if, for example, the desired appropriate distance for the lead mark is to be adjusted. In this context it is advantageous when an indexing element exhibits at least one depression.

This depression serves, on the one hand, as a mark, by means of which the indexed position can be indicated, and, on the other hand, it provides a simple and easy way of rotating the indexing element, since a pointed article, perhaps a ballpoint pen, can be pushed into this depression and the element therein can be relatively easily rotated against the force exerted by the rotary knob.

Theoretically, an indexing element can be provided with a number of depressions, but for exact and unambiguous indexing it is advantageous if each indexing element has only one depression.

In order to reliably prevent any unintentional adjustment of an indexing element when turning the rotary knob, it is advantageous if the exterior surface of the indexing element is offset toward the axis of rotation of the rotary knob in relation to the lateral surface of the rotary knob.

The invention is described below in more detail with reference to the drawings in which:

FIG. 1 shows an actuator according to the invention in a perspective cutaway view,

FIG. 2 shows the actuator of FIG. 1 in another cutaway section,

FIG. 3 shows a further section of the actuator in a perspective view,

FIG. 4 shows yet another section,

FIGS. 5 to 11 show different settings of the actuator for activating different modes of the actuator, and

FIG. 12 shows diagrammatically the adjustment range of a telescopic sight.

The invention described in this document relates to the positioning of a limit stop as well as to the definition of an adjustment range for a lead mark. Such adjustment, etc. is of particular advantage in connection with an actuator that permits indexing of the lead mark and, in particular, multiple indexing. The invention is therefore described below in more detail with reference to a specific actuator that permits multiple indexing. It may be pointed out, however, that the invention is also suitable for other actuators with multiple indexing or even for those that do not permit multiple indexing.

With the actuator shown, however, it is an advantage that the appropriate mechanism according to the invention can be particularly well accommodated in the rotary knob because of its special design.

The actuator BET shown consists, as can be seen in particular in FIGS. 1-4, in known manner, of, for instance, a rotary knob DRE that, when turned about its axis of rotation ACH, adjusts a reticle (lead mark) by means of the adjusting mechanism STE not illustrated in detail, which comprises, for example, a spindle. Depending on the arrangement of the actuator BET, this rotating motion results in an adjustment of the lead mark in a vertical or horizontal direction, or, if desired, in both horizontal and vertical directions. It is to be noted, however, that usually a separate actuator is used for adjustments in the horizontal direction and another one for adjustments in the vertical direction.

The rotary knob DRE usually consists, as illustrated, of a cylindrical housing, which, according to the invention, exhibits one or more recesses AS1, AS2, AS3, AS4 in its lateral surface MAN, into which recesses indexing elements IN1, IN2, IN3, IN4 are inserted. The indexing elements IN1-IN4 can be rotated in the peripheral direction in these recesses AS1-AS4.

In principle, to accommodate, for example, a number of indexing elements in an actuator of limited height, several indexing elements can be accommodated in one recess. For instance, with two indexing elements per recess, 8 indexing elements and thus 8 adjustment options would be created.

It is particularly advantageous, however, if just one indexing element is disposed in each recess, as shown, since in this case there is absolutely no likelihood of unintentional displacement of one or more other indexing elements not only when turning the rotary knob but also when one of the indexing elements is intentionally adjusted.

The actuator BET is particularly stable when the recesses AS1-AS4 are annular depressions in the lateral surface MAN of the rotary knob DER, as shown, in which the indexing elements IN1-IN4, which are also in the form of appropriately matching rings, are disposed.

The indexing elements do not necessarily have to be in the form of rings. For example, the indexing elements might well be small, block-like elements of minimal spread in the peripheral direction and displaceably disposed in the recesses. The use of such elements has the advantage of lower material costs and the creation of an indexing element which itself serves as a mark, whereas an indexing ring as shown in the drawings needs its own, additional mark, as explained below in more detail.

The use of indexing rings, however, has the advantage of simpler adjustability, since tilting, such as can occur with a block shaped element, is not possible, and furthermore the advantage of preventing dirt from ingress into the recesses AS1-AS4, so that long-term optimal operability is assured.

In addition, ring shaped indexing elements are advantageous because they automatically stay in the recesses due to their shape (at least when the ring covers more than a semi-circle), while measures must be taken with block shaped elements to ensure that they do not fall out of the recesses.

The indexing elements IN1-IN4 are entrained, preferably by friction, in the recesses AS1-AS4 as the rotary knob DRE is turned.

In the embodiment shown, in which the indexing elements are entrained by the rotary knob DRE by means of friction, it is only necessary to exert an appropriate, independent force on the respective indexing element to effect adjustment of the indexing elements IN1-IN4 relative to the rotary knob DRE.

This has the advantage, over the prior art, that the rotary knob DRE does not have to be loosened, and that due to the disposition of the indexing elements in separate recesses AN1-AN4, each indexing element can be simply and separately adjusted without the risk of the other indexing elements being inadvertently displaced.

It is, naturally, conceivable for each indexing element to be fastened by separate fastening means, for example by means of a screw, in the rotary knob DRE, and to be releasable for rotation. This provides a variant which is absolutely secure against unintentional displacement. In relation to the prior art, this embodiment exhibits the advantage that not all indexing elements have to be loosened for adjustment of one indexing element, but only the indexing element concerned. A disadvantage, however, is that “something” does have to be loosened, and in practice it has been found to be entirely sufficient for the avoidance of unintentional rotation of indexing elements (whether by turning the rotary knob or by adjusting an indexing element) to cause the indexing elements to be entrained by friction on rotation of the knob DRE.

In the advantageous embodiment shown, the recesses AN1-AN4 are designed in such a way that the indexing elements IN1-IN4 are slightly offset to the rear relative to the lateral surface MAN of the rotary knob DRE. This has the consequence that there is no risk of a force being unintentionally exerted on the indexing elements when the rotary knob DRE is turned such as could result when rotating the indexing elements.

Furthermore, the lateral surface exhibits fluting in the regions between the recesses to make the actuator easier to use.

In the embodiment shown, the actuator BET exhibits four indexing elements by means of which, for example, a rifle can be zeroed for four different shooting ranges, as mentioned at the outset. Depending on the shooting range, the marksman will move the appropriate mark of an indexing element IN1-IN4 or the appropriate indexing element itself with its mark MAK which is fixed in relation to the rifle, the so-called “zero-mark”, into position. This mark MAK is positioned on a fixed base SOC of the actuator BET or directly on the housing of the telescopic sight ZEF (see eg FIG. 7).

Reference is made, by way of example, to FIG. 4 showing four indexing rings IN1-IN4, which in each case exhibit a mark IM1-IM4 (FIG. 6). The mark IM1 of the top ring IN1 identifies, for example, a zero for 50 m, the mark IM2 of the second ring N2 for 100 m, the mark IM3 of the third ring IN3 for 150 m and the mark IM4 of the fourth ring IN4 for 200 m. If the marksman intends to shoot at a target at a range of 150 m, he will rotate the rotary knob DRE until the mark IM3 of the third indexing ring IN3 is in line with, ie opposite, the mark MAK.

The other marks or a point between two marks are selected for different distances, (for instance for 80 m, a position of the rotary knob DRE is selected at which the mark MAK lies between the marks IM1 and IM2).

Again, it is emphasized that this rotation of the rotary knob DRE to the position of the indexing elements IN1-IN4 has no effect on the rotary knob itself. The indexing elements themselves are only adjusted when zeroing, in which case force must be explicitly exerted on the same without the necessity, with this variant, of having to tighten or loosen the actuator.

As previously mentioned, it is necessary, when using indexing elements that extend over the entire periphery, for the indexing element itself to exhibit a mark which can be moved to be in line with the fixed mark on the telescopic sight by rotating the rotary knob DRE.

In the embodiment shown, this mark is a depression IM1-IM4 in the respective indexing element IN1-IN4. This embodiment has the advantage that, apart from the marking function by means of the depression, an indexing element can be particularly easily rotated, since one can insert a sharp object such as a pencil, ballpoint pen etc. into the depression and readily adjust the indexing element. In this case the (friction) force between the rotary knob and the indexing elements in the depressions can be relatively large so that it is no longer possible to effect (unintentional) rotation without the aid of a tool such as a pencil etc.

The actuator described is naturally particularly suitable, as explained above, for zeroing for a number of shooting ranges, for different ballistics, exchangeable barrels, etc. In principle, the invention is also suitable for zeroing a rifle barrel, for example, for just one range. In this case, it will naturally have only one indexing element.

In the context of the relationships described above the following may be noted:

-   -   The actuator can be used with one or more indexing elements.     -   A number of indexing elements can be disposed in one recess, but         it is an advantage to use only one indexing element per recess.     -   Each indexing element can be tightened and loosened in a recess         by means of fastening means (eg screws). This is particularly         advantageous when using a number of indexing elements per         recess. As shown above, however, an embodiment in which the         indexing elements are entrained by a friction connection is         simpler and better.     -   For n indexing elements there are n+1 indexing options, since         one operating range limit stop of the rotary knob can also be         used as an index mark.

Following these fundamental descriptions of the invention, it will now be described in greater detail.

As can be discerned from FIGS. 1-4, the turning range of the rotary knob DRE is limited by an operating range limit stop ANS in both directions of rotation. The rotary knob DRE is detachably coupled to the adjusting mechanism STE, and the at least one operating range limit stop ANS can be deactivated so that the rotary knob DRE can be rotated in both directions beyond the operating range limit stop ANS. Furthermore, the actuator BET can be switched between three different modes, and

-   -   a) in mode A the rotary knob DRE is coupled to the adjusting         mechanism STE and the operating range limit stop ANS is         inactive,     -   b) in mode B the rotary knob DRE is decoupled from the adjusting         mechanism STE and the operating range limit stop ANS is active,         and     -   c) in mode C the rotary knob DRE is coupled to the adjusting         mechanism STE and the operating range limit stop ANS is active.

Because of the detachable coupling of the rotary turret DRE to the adjusting mechanism STE, the entire mechanism for activating and deactivating the limit stop ANS can be integrated into the rotary knob whilst preserving full adjustability. Contamination is thereby prevented and no components can be lost. The possibility of setting the actuator to different modes, with two of these serving to establish the basic settings and the third representing the actual “operating mode” in which the lead mark is brought into a position corresponding to a certain shooting range by rotation of the rotary knob, adjustment and operation of the telescopic sight become much easier.

In one specific and advantageous embodiment, a limit stop element STI is positioned inside the rotary knob DRE, which, when the rotary knob DRE is turned, butts against the operating range limit stop ANS in a first, lower position, so that the operating range limit stop ANS is active, whilst in a second, upper position the limit stop element STI glides over the operating range limit stop ANS when turned, so that the operating range limit stop ANS is deactivated. Due to the fact that the entire stopping mechanism is disposed inside the rotary knob or actuator, the aforementioned advantages are achieved, that is to say, the disadvantages discussed above are avoided.

The invention can be realized and its subject assembled particularly easily if the limit stop element STI is a pin STI that is displaceable in a direction parallel to the axis of rotation ACH of the rotary knob DRE.

For coupling and decoupling the rotary knob to and from the adjusting mechanism, the rotary knob DRE is connected to a first coupler element KU1, which engages a second coupler element KU2, which is connected to the adjusting mechanism STE, so that when the rotary knob DRE is turned, the adjusting mechanism STE is entrained, and the first and second coupler elements KU1, KU2 can be disconnected from each other.

In a specific embodiment, the limit stop element and the first coupler element are separate entities, this being the simplest variant from the point of view of manufacturing technology and design engineering.

However, the limit stop element and the first coupler element could alternatively be built “as a single unit” such that, for instance, the limit stop element is mounted for vertical displacement in the form of a pin in the first coupling element. This represents an elegant variant which saves space inside the rotary knob, but it is more complicated as regards kinematics and with respect to production.

In principle, however, the limit stop element and the first coupler element might indeed be made as a single unit.

A simple embodiment ensuring readily disconnectable coupling and making available, in addition, a number of possible coupling positions between the rotary knob and the adjusting mechanism is realized if, as shown, the second coupler element KU2 contains one or more orifices OE1, OE2, OE3 . . . , which are disposed on the periphery of the adjusting mechanism STE, and the first coupler element KU1 is or has a projection VOS and the projection VOS engages an orifice OE1, OE2, OE3 in the coupled condition.

Another option is that the first and second coupler elements form a friction clutch, for example in that the first coupler element is a projection having a rubber lug that engages a rubber band disposed around the adjusting mechanism in the peripheral direction.

Simple deactivation or activation of the clutch can be realized when the first or second coupler element KU1, KU2 is adjustable in a direction parallel to the axis of rotation ACH for deactivation of the clutch.

For example, the second coupler element could be downwardly displaceable against the force of a spring.

In the embodiment shown, the second coupler element KU2 is rigidly connected to the adjusting mechanism STE. These can consist of two connected elements or alternatively be made as a single unit.

In the coupled condition, the rotating motion is transferred from the rotary knob DRE, in which the first coupler element KU1 can be moved up and down but not laterally in the peripheral direction, to the adjusting mechanism STE via the second coupler element KU2, which adjusts the lead mark. In the decoupled condition, the rotary motion is not transferred to the adjusting mechanism, since the first and second coupler elements do not engage one another so that the position of the lead mark remains unchanged when the rotary knob is turned.

A particularly simple, ergonomic and dirt-resistant adjustment system is realized when a rotatable control element ELS is disposed within the rotary knob DRE such that it can be rotated about the axis of rotation ACH relative to the rotary knob, and at the periphery of which, as shown, an operating cam KUR that interacts with the limit stop element STI, and the first coupler element KU1 runs so as to execute a continuous path that features a rising or falling path in certain regions of the periphery.

The operating cam KUR interacts with the limit stop element STI and the first coupler element KU1 because these elements STL, KU1 each exhibit an operating cam recess KSS (limit stop element STI) and KSK (first coupler element KU1), by means of which it engages the operating cam KUR. Both of these elements are mounted in the rotary knob for displacement in a direction parallel to the axis of rotation but lateral displacement in the peripheral direction is not possible. In the case of a fixed rotary knob, one of the two elements STI, KU1 is then moved up or down as the control element ELS is rotated by means of the cam and the other one remains in its vertical position. Alternatively, both elements may be moved, one upwardly, the other downwardly.

When the limit stop element and first coupler element are separate from each other, it is sufficient to have only one operating cam on the control element, which cam, when rotated through its specific path, for example lifts the first coupler element from the second coupler element while the limit stop remains active, etc.

If the two elements can be interleaved, as described above, and thus disposed one directly above the other, a separate operating cam is necessary for each element (limit stop element and first coupler element).

The position of the control element can be locked in relation to the rotary knob DRE so that the control element cannot be turned unintentionally so as to activate another mode when the rotary knob is turned.

The aforementioned effect can be achieved in an even simpler way and with the same result when, as shown, the control element ELS is coupled to the rotary knob DRE by means of friction. In the case of a frictional connection between the rotary knob and the control element, turning the control element with an appropriate application of force while simultaneously holding the rotary knob is sufficient to activate another mode. If on the other hand the rotary knob is rotated, the control element is simply entrained by the friction forces between the rotating knob and the control element.

The control element ELS itself is conveniently mounted in the rotary knob DRE for rotation, and the cover surface AFS of the control element ELS is substantially flush with the top surface DFD of the rotary knob DRE.

In order to make it possible to simply rotate the control element to activate the different modes, the control element ELS exhibits one or more orifices OEF in its top surface for the insertion of a key SSE, and by means of said key SSE the control element ELS can be rotated relatively to the rotary knob DRE.

In the case of a friction coupling between the control element and the rotary knob, as shown, this key has only the function of making it possible to turn the control element in the rotary knob more easily and it does not, however, have any sort of key “function” in the sense of something being “locked”.

However, a fixed position of the control element relative to the rotary knob can be deactivated and re-activated by means of the key, if means for such mechanical position fixing are provided. In the case of deactivated position fixing, the control element can be simply turned by means of the key.

In order to show the position of the lead mark in relation to the entire adjustment range, the adjusting mechanism STE exhibits a displacement indicator element IND in its upper region that is moved up or down in an appropriate opening in the control element ELS when the adjusting mechanism STE is rotated about an axis parallel to the axis of rotation ACH and, depending on its position, the top surface of said element IND is positioned above, or flush with, or below the cover surface DFD of the rotary knob DRE or the cover surface AFS of the control element ELS.

This displacement indicator element IND is, for example, in the form of an attachment to the adjusting mechanism STE, although the indicator element and the adjusting mechanism may be embodied as a single unit, if desired. The displacement indicator element is raised or lowered accordingly by the up and down movements of the adjusting mechanism, ie the spindle. If the displacement indicator element is in a position very far in or out of the actuator following assembly and initial zeroing of the telescopic sight, this points to poor assembly, which can have the result that the adjustment range can no longer be exploited entirely.

FIG. 5 shows yet another actuator BET of the described type having a key SSE on a telescopic sight ZEF. The rotary knob DRE is in this case mounted on a base SOC that is fixed relative to the telescope.

In the following, FIGS. 6 to 11 show by way of example a step by step repeated procedure of zeroing the actuator for different shooting ranges in diagrammatic representation.

In a similar way, it is possible to effect deflective adjustments and/or, for example, multiple zeroing for various ballistics, exchangeable barrels, windage corrections, etc.

The mechanics in the vertical adjustment turret illustrated correspond to those in the horizontal adjustment turret.

FIG. 6: Using the key SSE, the control element ELS (the “mode dial”) is turned to position A. The mode mark ELM points to A. In mode A, the rotary knob (“adjusting knob”) adjusts the lead mark over the entire adjustment range, cf. FIG. 12. The selectable stop ANS is inactive.

The user now selects a minimum shooting range, for example, 100 meters and sets the lead mark exactly over the point of impact that is attained at 100 meters by rotating the adjustment turret accordingly.

FIG. 7: Using the key SSE, the mode dial ELS is turned to position B. The mode mark ELM points to B. In mode B, the rotary knob of the adjusting mechanism STE is decoupled. The selectable stop ANS is active.

The user now rotates the adjustment turret anticlockwise as far as the limit stop (left-hand stop). This limit stop now corresponds to the (lower) operating range limit stop, defined by the operating range limit stop device ANS (in the specific embodiment, the operating range limit stop device ANS defines both the lower and the upper operating range limit stops, ie the entire adjustment range), so that the adjustment range AVB is established in relation to the entire adjustment range SBM (cf. FIG. 12).

The lower operating range limit stop now corresponds exactly to the main index mark and now indexes zeroing for 100 meters.

FIG. 8: Using the key SSE, the mode dial ELS is turned to C. The mode mark ELM points to C. In mode C the rotary knob adjusts the lead mark from the selected left-hand stop within a full turn in the clockwise direction. The operating range limit stop and the adjusting mechanism are thus active.

FIG. 9: The user now selects another shooting range, for example, 200 meters and adjusts the lead mark to exactly the point of impact that is attained at 200 meters by rotating the rotary knob in the clockwise direction.

FIG. 10: The user now pushes one of the individually variable indexing elements to a position opposite the main index mark (“zero-mark”) MAK. The selected index mark now indexes zeroing for 200 meters.

FIG. 11: All other desired shooting ranges (for example 300, 400, 500 meters) are zeroed with the index marks still available. 

1. An actuator for adjusting a lead mark of a telescopic sight, in which the actuator is in the form of a rotary knob mounted on the telescopic sight for rotation, which rotation of said rotary knob adjusts a position of the lead mark via an adjusting mechanism in a vertical and/or horizontal direction, and in which a turning range of said rotary knob is restricted by at least one operating range limit stop in both directions of rotation, wherein the rotary knob is releasably coupled to said adjusting mechanism; the at least one operating range limit stop can be deactivated such that the rotary knob can be turned in both directions beyond said at least one operating range limit stop; and the actuator can be switched between at least three different modes: a) in mode A the rotary knob is coupled to the adjusting mechanism and the at least one operating range limit stop is inactive, b) in mode B the rotary knob is decoupled from the adjusting mechanism and the at least one operating range limit stop is activated, and c) in mode C the rotary knob is coupled to the adjusting mechanism and the at least one operating range limit stop is activated.
 2. The actuator as defined in claim 1, wherein in the interior of the rotary knob there is provided a limit stop members, which, when turned in a first, lower position butts against the at least one operating range limit stop so that the at least one operating range limit stop is active, and when turned in a second, upper position, the limit stop member travels beyond said at least one operating range limit stop so that said at least one operating range limit stop is deactivated.
 3. The actuator as defined in claim 2, wherein the at least one limit stop member is a pin which is displaceable in a direction parallel to an axis of rotation of the rotary knob.
 4. The actuator as defined in claim 1, wherein said rotary knob is connected to a first coupler element, which engages a second coupler element that is connected to said adjusting mechanism such that when said rotary knob is turned, said adjusting mechanism is entrained, and the first and second coupler elements can be disengaged.
 5. The actuator as defined in claim 4, wherein the second coupler element comprises one or more orifices or projections disposed at the periphery of said adjusting mechanism, and the first coupler element has or is a projection or orifice, and in a decoupled state a projection engages an orifice.
 6. The actuator as defined in claim 4, wherein the first and second coupler elements form a friction clutch.
 7. The actuator as defined in claim 4, wherein the first or second coupler element can be displaced in a direction parallel to tan axis of rotation of the rotary knob for the purpose of declutching.
 8. The actuator as defined in claim 2, wherein in the interior of the rotary knob there is disposed a control element that is rotatable about an axis of rotation relatively to said rotary knob, at least one operating cam being adapted to rotate around the periphery of said control element and to cooperate with said at least one limit stop member and the first coupler element, which at least one operating cam follows a continuous path showing rising or falling sections in certain peripheral regions.
 9. The actuator as defined in claim 8, wherein said control element can be fixed in position relatively to said rotary knob.
 10. The actuator as defined in claim 8, wherein said control element is coupled to said rotary knob by means of a friction clutch or power clutch.
 11. The actuator as defined in claim 8, wherein said control element is rotatably mounted in said rotary knob itself.
 12. The actuator as defined in claim 8, wherein an upper cover plate of said control element is substantially flush with a cover surface of said rotary knob.
 13. The actuator as defined in claim 8, wherein said control element has at its top surface one or more orifices for the accommodation of a key, and by means of said key the control element can be rotated relatively to said rotary knob.
 14. The actuator as defined in claim 1, wherein the adjusting mechanism has in its upper region a displacement indicator, which, when said adjusting mechanism is turned, is moved upwardly or downwardly in a direction parallel to an axis of rotation into a corresponding orifice in said control element and, depending on its position, is flush with, projecting above, or positioned below, a cover surface of said rotary knob or a cover plate of said control element.
 15. The actuator as defined in claim 1, wherein said rotary knob has one or more indexing elements, by means of which one or more positions of the lead mark can be indexed, wherein in an actuating mode rotation of said rotary knob entrains the one or more indexing elements therewith and in an indexing mode the one or more indexing elements can be displaced in a peripheral direction of said rotary knob independently of the rotary knob, and said rotary knob has one or more recesses on its lateral surface in the peripheral direction, and in at least one of the one or more recesses at least one of the one or more indexing elements is mounted for rotation in the peripheral direction, and wherein the one or more indexing elements is coupled to said rotary knob via its/their one or more recesses in such a manner that when said rotary knob is turned it/they are entrained therewith.
 16. The actuator as defined in claim 15, wherein in each of the one or more recesses there is disposed at least one indexing element.
 17. The actuator as defined in claim 15, wherein the one or more indexing elements are coupled via a frictional connection or a friction lock to said rotary knob in said one or more recesses.
 18. The actuator as defined in claim 15, wherein in each of the one or more recesses there is disposed just one indexing element.
 19. The actuator as defined in claim 15, wherein the one or more recesses each form a closed ring around the lateral surface.
 20. The actuator as defined in claim 15, wherein each of the one or more indexing elements is in the form of a ring section or a closed ring.
 21. The actuator as defined in claim 15, wherein each of the one or more indexing elements has at least one depression.
 22. The actuator as defined in claim 15, wherein the external surface of each of the one or more the indexing elements is offset from the lateral surface of said rotary knob in the direction of an axis of rotation of said rotary knob.
 23. A telescopic sight having an actuator as defined in claim
 1. 